Desert dust aerosol columnar properties over ocean and continental Africa from Lidar in‐Space Technology Experiment (LITE) and Meteosat synergy

Berthier, S.; Chazette, Patrick; Couvert, P.; Pelon, Jacques; Dulac, François; Thieuleux, F.; Moulin, C.; Pain, Thierry

doi:10.1029/2005jd006999

Cited by 74 publications

(66 citation statements)

References 98 publications

(136 reference statements)

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“…It corresponds also to a low (52 µg/m 3 ) PM 10 at the ground-level highlighting that most of the dust is transported in the aloft layer. Such vertical structure of the dust transport has also been observed by Berthier et al (2006) from the LITE spaceborne lidar over the Tropical Atlantic Ocean off the western African coast. Figure 11b presents the biomass burning aerosol profiles (SSA below 0.85).…”

Section: Vertical Profiles By Aerosol Typesmentioning

confidence: 64%

Aerosol vertical distribution and optical properties over M'Bour (16.96° W; 14.39° N), Senegal from 2006 to 2008

et al. 2009

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Abstract. We present ground-based measurements of aerosol mass, optical properties and vertical extinction profiles acquired in M'Bour, Senegal (16.96° W; 14.39° N) from January 2006 to September 2008. This place of the world is all year long affected by the export of mineral dust as it moves westward to the north Atlantic ocean. The maximum in the dust activity is observed in summer (June–July), corresponding to a maximum in the aerosol optical thickness (above 0.5) and single scattering albedo (above 0.95). It also corresponds to a maximum in the top altitude of the transported aerosol layer (up to 6 km) and aerosol optical thickness scale height (up to 3.5 km) due to the presence of the Saharan Air Layer located between 2 and 6 km. The late summer shows an additional low level aerosol layer that increases in thickness in autumn. Severe dust storms are also systematically observed in spring (March) but with a lower vertical development and a stronger impact (factor 2 to 3) on the ground-level mass compared to summer. Sporadic events of biomass burning aerosols are observed in winter (January) and particularly in January 2006 when the biomass burning aerosol are advected between 1.5 and 3.5 km high. On average, the seasonal signal in the aerosol optical properties and vertical distribution is very similar from year to year over our 3 year monitoring.

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Section: Vertical Profiles By Aerosol Typesmentioning

confidence: 64%

Aerosol vertical distribution and optical properties over M'Bour (16.96° W; 14.39° N), Senegal from 2006 to 2008

et al. 2009

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“…LITE (Lidar Inspace Technology Experiment; McCormick et al, 1993), GLAS (Geoscience Laser Altimeter System; Spinhirne et al, 2005) and CALIPSO (Cloud-Aerosol Lidar and Infrared Pathfinder Satellite Observations; Winker et al, 2004Winker et al, , 2006Winker et al, , 2007) of atmospheric aerosols and clouds is the key for providing global vertically resolved observations that are needed to better understand a variety of aerosol-cloud radiationclimate feedback processes (e.g. Spinhirne et al, 2005;Berthier et al, 2006).…”

Section: Introductionmentioning

confidence: 99%

Validation of CALIPSO space-borne-derived attenuated backscatter coefficient profiles using a ground-based lidar in Athens, Greece

et al. 2009

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Abstract. We present initial aerosol validation results of the space-borne lidar CALIOP -onboard the CALIPSO satelliteLevel 1 attenuated backscatter coefficient profiles, using coincident observations performed with a ground-based lidar in Athens, Greece (37.9 • N, 23.6 • E). A multi-wavelength ground-based backscatter/Raman lidar system is operating since 2000 at the National Technical University of Athens (NTUA) in the framework of the European Aerosol Research LIdar NETwork (EARLINET), the first lidar network for tropospheric aerosol studies on a continental scale. Since July 2006, a total of 40 coincidental aerosol groundbased lidar measurements were performed over Athens during CALIPSO overpasses. The ground-based measurements were performed each time CALIPSO overpasses the station location within a maximum distance of 100 km. The duration of the ground-based lidar measurements was approximately two hours, centred on the satellite overpass time. From the analysis of the ground-based/satellite correlative lidar measurements, a mean bias of the order of 22% for daytime measurements and of 8% for nighttime measurements with respect to the CALIPSO profiles was found for altitudes between 3 and 10 km. The mean bias becomes much larger for altitudes lower that 3 km (of the order of 60%) which is attributed to the increase of aerosol horizontal inhomogeneity within the Planetary Boundary Layer, resulting to the observation of possibly different air masses by the two instruments. In cases of aerosol layers underlying Cirrus clouds, comparison results for aerosol tropospheric profiles become worse. This is attributed to the significant multiple scattering effects in Cirrus clouds experienced by CALIPSO which result in an attenuation which is less than that measured by the ground-based lidar.

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“…The multiple scattering (MS) contributions are taken into account through the MS coefficient η [29], and depend on the wavelengths [66]. As previously explained (Section 2.2.3), this effect is negligible in UV (355 nm, η ≈ 1), but not in NIR (1064 nm, η ≈ 0.96).…”

Section: Multiple Scattering Effectsmentioning

confidence: 81%

“…These BER values were used in the following simulations and supposed constant in the canopy. Multiple scattering coefficient (η), at different depths in the scattering layer, is deduced from the ratio between the total lidar signal (including single scattering Ssingle and multiple scattering Smultiple) and the number of single-backscattered photon as [29]:…”

Section: Surface Characteristicsmentioning

confidence: 99%

End-to-End Simulation for a Forest-Dedicated Full-Waveform Lidar Onboard a Satellite Initialized from Airborne Ultraviolet Lidar Experiments

Shang

Chazette

2015

Remote Sensing

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Abstract:In order to study forests at the global scale, a detailed link budget for a lidar system onboard satellite is presented. It is based on an original approach coupling airborne lidar observations and an end-to-end simulator. The simulator is initialized by airborne lidar measurements performed over temperate and tropical forests on the French territory, representing a wide range of forests ecosystems. Considering two complementary wavelengths of 355 and 1064 nm, the end-to-end simulator computes the performance of spaceborne lidar systems for different orbits. The analysis is based on forest structural (tree top height, quadratic mean canopy height) and optical (forest optical thickness) parameters. Although an ultraviolet lidar appears to be a good candidate for airborne measurements, our results show that the limited energy is not favorable for spaceborne missions with such a wavelength. A near infrared wavelength at 1064 nm is preferable, requiring ~100 mJ laser emitted energy, which is in agreement with current and future spaceborne missions involving a lidar. We find that the signal-to-noise ratio at the ground level to extract both the structural and optical parameters of forests must be larger than 10. Hence, considering the presence of clouds and aerosols in the atmosphere and assuming a stationary forest, a good detection probability of 99% can be reached when 4 or 5 satellite revisits are considered for a lidar system onboard the ISS or ICESat, respectively. This concerns ~90% of forest covers observed from the lidar, which have an optical thickness less than 3. OPEN ACCESSRemote Sens. 2015, 7 5223

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Desert dust aerosol columnar properties over ocean and continental Africa from Lidar in‐Space Technology Experiment (LITE) and Meteosat synergy

Cited by 74 publications

References 98 publications

Aerosol vertical distribution and optical properties over M'Bour (16.96° W; 14.39° N), Senegal from 2006 to 2008

Aerosol vertical distribution and optical properties over M'Bour (16.96° W; 14.39° N), Senegal from 2006 to 2008

Validation of CALIPSO space-borne-derived attenuated backscatter coefficient profiles using a ground-based lidar in Athens, Greece

End-to-End Simulation for a Forest-Dedicated Full-Waveform Lidar Onboard a Satellite Initialized from Airborne Ultraviolet Lidar Experiments

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